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Canadian Spatial Reference System
Earth Sciences Sector
Making Sense of Evolving Datums:WGS84 and NAD83
Mike CraymerGeodetic Survey DivisionNatural Resources Canada
Presented atHydroscan 2006, Saskatoon, September 22, 2006
AbstractThe World Geodetic System 1984 (WGS84) and North American Datum of 1983 (NAD83) are presently the most widely-used spatial reference systems in North America. NAD83 is the national reference system used for georeferencing by mostfederal and provincial/state agencies in Canada and the U.S. while WGS84 is the default "native" system used by the GlobalPositioning System (GPS) and commercial GPS receivers. The physical realization of these reference systems haveundergone several updates since they were first introduced over two decades ago. NAD83 has evolved from a traditional,ground-based horizontal control network to a space-based 3D realization fully supporting modern GPS techniques and theintegration of both horizontal and vertical reference systems. WGS84, on the other hand, has no publicly accessible ground-based network. It is accessible only via broadcast orbits that provide positions with an accuracy of about a meter at best(with augmented corrections).
Originally, NAD83 and WGS84 were based on the same global datum using an older satellite positioning system calledTransit or Doppler. The reference systems were thus completely compatible with each other. However, they diverged in1994 when WGS84 was redefined with GPS based on a more accurate reference system called the International TerrestrialReference Frame (ITRF). This redefinition occurred two more times using more recent and more accurate versions of theITRF.
The redefinition of WGS84 resulted in coordinates differences of up to 1.5 m horizontally and 1 m vertically with respect toNAD83 in Canada. Although the national geodetic agencies in both Canada and the U.S. adopted a common transformationbetween NAD83 and the various ITRFs for use with the new realizations of WGS84, the bias between NAD83 and WGS84was never acknowledged by the agency maintaining WGS84. Consequently, the vast majority of GPS receivermanufactures continue to treat NAD83 as being identical with the new realizations of WGS84 which results in positionerrors of over a meter. Moreover, ITRF-based systems are global systems in which all the continents are in continuousmotion due to the Earth’s tectonic forces while NAD83 is fixed to the North American tectonic plate and move with it.Consequently, NAD83 moves at about 2.5 cm/y relative to the ITRF/WGS84 systems.
Details of the adopted NAD83transformations are provided to allow users to properly account for these differences betweenNAD83 and ITRF-based systems such as WGS84 in a consistent way throughout North America. For further informationsee M. Craymer (The Evolution of NAD83 in Canada. Geomatica, Vol. 60, No. 2, pp. 151-164.<ftp://geod.nrcan.gc.ca/pub/GSD/craymer/pubs/nad83_geomatica2006.pdf>).
Outline
Some basic concepts Old Systems:
World Geodetic System 1984 (WGS84) North American Datum of 1983 (NAD83)
Modern Systems: International Terrestrial Reference Frame (ITRF) WGS84(G…) NAD83(CSRS)
Some practical issues
Basic Concepts
Spatial Reference System A prescription for physically realizing a reference
system Orderly collection of logically related principles, facts, objects
and techniques that can be used for a quantitative descriptionof positions and motions in space
Datum Theoretical reference surface Geometric model of the Earth
Reference ellipsoid Semi-major axis (equatorial
radius) Semi-minor axis (polar radius) Aligned with coordinate system
Basic Concepts (con’t)
EllipsoidHeight
Semi-major axis
Semi-major axis
FlatteningFlattening
EllipsoidEllipsoid
P P
XY
ZNorth Pole
Earth’scentre of
mass
y x
z
Gre
enw
ich
Mer
idia
nEquator
Basic Concepts (con’t)
Spatial Reference Frame Physical realization of a Spatial Reference System Usually a network of monumented points
Established using geodetic survey techniques Published coordinates define the frame New realizations/versions as technology evolves
Old Reference Frames
WGS84NAD83
Original WGS84
Native reference frame of GPSDatum
WGS84 ellipsoid (=GRS80)Based on Doppler & BTS84
Aligned to international BTS84 Near-geocentric +/- 1 m (best could do at the time)
No physical ground network or coordinates Satellites (brdcst orbits) are only accessible “control” Enables point positioning only: 1-10 m accuracy
Geoid
Geocentred on Earth’scentre of mass (asknown in 1986)
WGS84 Ellipsoid
Original NAD83
National reference system in Canada & U.S.Datum
GRS80 ellipsoid (=WGS84)Defined same as WGS84
Identical to WGS84 Fixed to North American plate
Physical realization Traditional control networks & published coordinates
Limitations of Original WGS84/NAD83
Revealed by advances in GPS1) Non-geocentric
Offset from geocenter by about a meter Incompatible with modern reference frames
2) NAD83 primarily a horizontal reference frame Densified using traditional 2D survey methods Errors of up to 1 m and more
Errors in NAD83(Original)
Modern Reference Frames
ITRFWGS84 “G” series
NAD83(CSRS)
International TerrestrialReference Frame
Best geocentric system available Stable to about a cm Maintained by IERS under auspices of IAG Primarily for scientific community & national datums
Dynamic system Coordinates changing due to plate tectonics
Valid only for a specific date (epoch) Velocities provided to update to other epochs
Frequent new realizations Due to more data & improved techniques
ITRF88ITRF89ITRF90ITRF91ITRF92ITRF93ITRF94ITRF96ITRF97ITRF2000ITRF2005
Plate Tectonic Motions
2 cm/y
WGS84 “G” Series
Original WGS84 Realigned to ITRF (shifted/reoriented) Greater accuracy & stability Compatible with internationally adopted ITRF
Version Based on IntroducedWGS84(G730) ITRF91 1994WGS84(G873) ITRF94 1996WGS84(G1150) ITRF2000 2002
Introduced a coordinate shift In Canada: 1.5 m horiz. 0.2-1.0 m vert. Not noticeable in WGS84 (+/- 1 m) but is in NAD83
WGS84(Orig)/NAD83 vs WGS84(G1150)/ITRF2000
NAD83(CSRS)
Defined as a best fitting transformation from ITRF Also models tectonic motion of North America As accurate & stable as ITRF Adopted in Canada and U.S. Transformation updated for new ITRFs Web & software tools available (www.geod.nrcan.gc.ca)
Still compatible with NAD83(Orig) Differences due to errors in original Different from new WGS84(G…) by 1.5 m !!
1997 WGS84(G873)- aligned with ITRF94
1998 NAD83 (CSRS)- same NAD83 reference system- same geocentre offset/misalign- transformation from ITRF- cm-accuracy NAD83
NAD83 WGS84 ITRF
2001 WGS84(G1150)- aligned with ITRF2000
ITRF89ITRF90
ITRF91ITRF92ITRF93
ITRF94ITRF96ITRF97
ITRF2000
Smallincrementalchanges
1988 ITRF88- geocentric
Dynamic
1986 NAD83 (Orig)- NAD83 reference systembased on Doppler- Coordinate shifts of 1.5 mhorizontally, 1 m vertically- metre-accuracy NAD83
Fixed
1987 WGS84 (Orig)- same as NAD83- +/- 1 m accuracy
Fixed
1994 WGS84(G730)- aligned with ITRF91
Dynamic
1.5 m shift
Practical Issues
NGA Datum Shift for NAD83Correction Sevices
NGA (publishers of WGS84) official datum shift table
Used by majority of GSP receivers Set receiver to NAD83 Zero datum shift applied (incorrect) Still in WGS84 -- need to transform using adopted procedure
http://earth-info.nga.mil/GandG/publications/tr8350.2/tr8350_2.html
NGA Datum Shift for NAD83
NAD83-WGS843 parameter shift
(incorrect)
Correction Services
Reference frame depends on service/source Uncorrected or WAAS corrections
Receiver positions always in WGS84 Still in WGS84 if NGA (zsero) shift to NAD83 applied
CDGPS or Coast Guard corrections Receiver positions in NAD83(CSRS) Falls back to WGS84 without warning if service signal lost
Post-processing with CSRS-PPP User selects either NAD83(CSRS) or ITRF/WGS84(G)
CSRS Database (“published” values) Either NAD83 or NAD83(CSRS)
For More Information
Craymer, M. (2006). The evolution of NAD83 inCanada. Geomatica, Vol. 60, No. 2, pp. 151-164.<ftp://geod.nrcan.gc.ca/pub/GSD/craymer/pubs/nad83_geomatica2006.zip>
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